# Map renderer This document specifies the map renderer in `ui/frontend/src/map/`. It is the source of truth for the rendering data model, the hit-test algorithm, the torus-wrap and bounded-plane (no-wrap) camera semantics, and the choice of dependencies. Any disagreement between this document and the code is a bug in one of them. > **`galaxy/client` is deprecated.** The Go module under > `galaxy/client/` — including `client/world/` — is no longer the > reference implementation for any new code. The TypeScript > renderer described here is independent: it does not import > `client/world` at runtime, and it is not bound by the older > module's algorithmic details (fixed-point integers, expanded > canvas, incremental pan reuse, grid spatial index). The Go code > remains as historical context only. ## Goals The renderer is the bottom of the rendering stack the rest of the UI sits on top of. It must: 1. Render thousands of vector primitives (points, circles, lines) onto a Pixi v8 canvas at 60 fps on a mid-range laptop. 2. Support pan and zoom over a toroidal world (`'torus'` mode) and over a bounded plane (`'no-wrap'` mode), both first-class. 3. Run the same algorithm on web, Wails, Capacitor, and PWA targets — no API in this module assumes the platform. 4. Provide deterministic hit-test for cursor-to-primitive mapping, with results that are unit-testable independently of Pixi. ## Coordinate model World coordinates are TypeScript `number` (IEEE 754 float64). The world is a rectangle `[0, W) × [0, H)` for some positive `W`, `H`. Primitive geometry, the camera centre, and the no-wrap clamp arithmetic all live in world coordinates. Pixi's transform pipeline owns the world→screen mapping. We do not maintain a manual fixed-point representation: the deprecated Go renderer's fixed-point ints existed because it composited into a pixel buffer, which we do not. The camera is `{ centerX, centerY, scale }` with `scale` in pixels per world unit. The viewport is `{ widthPx, heightPx }` in CSS pixels (Pixi's `autoDensity` handles device pixel ratio internally). ## Primitives ```ts type Primitive = PointPrim | CirclePrim | LinePrim; interface PrimitiveBase { id: PrimitiveID; priority: number; style: Style; hitSlopPx: number; // 0 = use kind default } interface PointPrim extends PrimitiveBase { kind: 'point'; x: number; y: number; } interface CirclePrim extends PrimitiveBase { kind: 'circle'; x: number; y: number; radius: number; } interface LinePrim extends PrimitiveBase { kind: 'line'; x1: number; y1: number; x2: number; y2: number; } ``` `radius` is in world units. `style.strokeWidthPx` and `style.pointRadiusPx` are in screen pixels and stay constant under zoom (Pixi's stroke width is in pixel space when the parent container is scaled). Default hit slop in screen pixels: point=8, circle=6, line=6. These are touch-ergonomic defaults; per-primitive `hitSlopPx > 0` overrides them. ## Theme A single dark theme is implemented. The theme is a record of default colours; primitives whose `style` omits a colour fall back to the theme. Runtime theme switching is not implemented — light/dark and the materialise-on-theme-change cycle are deferred to the finalization plan ([../PLAN-finalize.md](../PLAN-finalize.md)). ## Hit-test Algorithm in `src/map/hit-test.ts`: ```text hitTest(world, camera, viewport, cursorPx, mode): cursorWorld = screenToWorld(cursorPx, camera, viewport) candidates = [] for p in world.primitives: slopPx = p.hitSlopPx > 0 ? p.hitSlopPx : DEFAULT[kind] slopWorld = slopPx / camera.scale delta = mode == 'torus' ? torusShortestDelta(p, cursorWorld, world) : euclideanDelta(p, cursorWorld) distSq = match(delta, p.kind, p.geometry, slopWorld) // or null if distSq != null: candidates.push({ p, distSq }) candidates.sort(by [-priority, distSq, kindOrder, id]) return candidates[0] ?? null ``` `torusShortestDelta` normalises a delta to the half-open interval `(-size/2, size/2]` per axis, picking the shorter wrap direction. At exactly `size/2` it returns `+size/2` (positive direction); the lower bound is exclusive so `-size/2` is normalised to `+size/2`. `kindOrder` is `point=0, line=1, circle=2`. Point wins ties over overlapping line/circle; this matches typical UX expectations where a point object on top of a route should be the preferred target. Per-primitive distance: - **Point**: `distSq ≤ (pointRadiusPx + slopWorld)²`. The visible disc is part of the click target — a click on any pixel of the rendered planet registers as a hit, with `slopWorld` adding a small ergonomic margin on top. `pointRadiusPx` defaults to `DEFAULT_POINT_RADIUS_PX = 3` when unset. - **Filled circle**: `distSq ≤ (radius + slopWorld)²` where `radius` is in world units. The circle counts as filled when `style.fillColor` is set and `style.fillAlpha > 0`. - **Stroke-only circle**: `|dist - radius| ≤ slopWorld`. The squared "distance" reported is the squared ring gap, so the ordering rule prefers the closest-to-ring candidate among multiple ring-only circles. - **Line**: perpendicular distance to the segment, with `t` clamped to `[0, 1]` (foot beyond endpoints uses the endpoint). In torus mode the segment is taken in its torus-shortest representation: from `(x1, y1)` to `(x1 + dx, y1 + dy)` where `(dx, dy)` is the torus-shortest delta from end-1 to end-2. The brute-force `O(N)` walk is fine for the current target of ~1000 primitives on every pointer event. Spatial indexing is deferred until profiling proves it necessary; PixiJS' culling and batching handle the draw side without help. ## Torus rendering The renderer creates nine container copies of the primitive scene at offsets `(dx, dy) ∈ {-W, 0, W} × {-H, 0, H}`. In torus mode all nine copies are visible; PixiJS culls the off-viewport copies itself. In no-wrap mode only the origin copy `(0, 0)` is visible. Lines that cross a torus boundary are not split at render time: each copy renders the full line at its offset, and PixiJS' culling naturally drops the parts outside its container's reachable area. The nine-copy upper bound assumes the visible viewport never exceeds three tile-widths or three tile-heights of the world. To hold this assumption in both modes, the renderer enforces `clampZoom({ minScale })` with `minScale = max(viewport.W/world.W, viewport.H/world.H)` regardless of wrap mode. Without this, in torus mode the user could zoom out far enough to see the 3×3 grid of wrap copies at once — the copies are there to fill partial slack near a panned edge, not to be visible simultaneously. The clamp is re-evaluated on every viewport resize so a window resize does not strand the camera below the new minimum. ## No-wrap camera `pixi-viewport`'s built-in `clamp({ direction: 'all' })` plugin keeps the camera inside the world rectangle by default. We layer the project-specific centring rule on top, implemented via the `'moved'` event: when the visible viewport is larger than the world along an axis, the camera is **centred** on that axis. `pixi-viewport`'s default would pin the world to the top-left of the screen, which is jarring at low zoom. The shared `clampZoom({ minScale })` (described above) prevents this case in practice, but the centring rule stays as a defensive layer for windowed-resize transients. `pivotZoom` keeps the world point under the cursor stable during zoom. The math is symmetric and tested in `tests/map-no-wrap.test.ts`. ## Dependencies - **`pixi.js@^8`** — vector renderer with WebGPU/WebGL backend. Async init via `app.init({ preference, ... })`. The `preference` option may be a string or an array; the renderer cascades through the array and falls back to whichever backend initialises successfully. - **`pixi-viewport@^6`** — pan/zoom/pinch plugin layer over a Pixi `Container`. Provides drag, mobile gestures, and the `clamp`/`clampZoom` plugins out of the box. We disable the plugins we do not need (`bounce`, `snap`, `follow`, `mouse-edges`) and deliberately omit `decelerate`: a released drag stops immediately instead of coasting, which also lets render-on-demand (below) go idle the moment the pointer is up. No additional dependencies are necessary. The deprecated `pixi.js`-v7 era `pixi-viewport` v5 contracts have been replaced in v6 (notably `events: renderer.events` is now mandatory in the constructor). ## Renderer preference selection The playground page reads `?renderer=webgpu|webgl` from the URL and passes it to `Application.init`. Without the parameter the preference defaults to `['webgpu', 'webgl']`. Playwright projects use the URL parameter to force a specific backend per browser: - `chromium-desktop` → `?renderer=webgpu` - `webkit-desktop` → `?renderer=webgl` (WebKit does not implement WebGPU yet) - mobile projects → no parameter, accept whichever Pixi picks The selected backend is exposed via `[data-backend]` on the playground page header so the e2e spec can assert it without poking Pixi internals. ## Render-on-demand Pixi's continuous auto-render loop is stopped right after `Application.init` (`app.stop()`). Frames are painted explicitly by a single gated flush added to `Ticker.shared` — the same ticker pixi-viewport already drives, so no second timer is created: ```ts if (viewport.dirty || contentDirty) { app.render(); /* reset both */ } ``` - `viewport.dirty` is maintained by pixi-viewport's own update and covers every camera change (drag / wheel / pinch, the torus and no-wrap `moved` listeners, programmatic `moveCenter`). - `contentDirty` is set by an internal `requestRender()` from every scene-graph mutation that does not move the camera: `setVisibilityFog`, `setHiddenPrimitiveIds`, `setExtraPrimitives`, `applyMode`, `resize`, and the pick-mode overlay redraw. - Plain hover mutates no `Graphics`, so moving the cursor over the map paints nothing. An idle map therefore does zero GPU work per frame. This matters for the visibility fog: its layered overpaint is fill-heavy, and a continuously re-rendered fog froze the whole UI on large reports in Safari (Pixi's WebGPU backend). `RendererHandle.getRenderCount()` exposes the painted-frame count; the `map-toggles` e2e spec asserts with it that an idle map does not repaint and that a released drag does not coast. ## Performance acceptance The "60 fps with 1000 primitives" criterion is documented but manually verified, not asserted in CI. CI runners vary too much in CPU/GPU to make wall-clock fps reliable. Manual gate: open `/__debug/map`, drag continuously for 5 seconds, and watch the frame rate in the browser DevTools rendering meter (the app ticker is stopped under render-on-demand, so `app.ticker.FPS` no longer tracks paints — frames land via the `Ticker.shared` flush only while the camera is moving). If a future regression requires a programmatic perf gate, the right place is a Tier 2 (release-line) Playwright trace measuring average frame time over a scripted drag. ## Pick mode The renderer provides a generic *map-driven destination pick* that the inspector uses for cargo routes and ship-group dispatch. The renderer owns the visual lifecycle; the Svelte side wraps it in a promise-shaped service. Lifecycle (`RendererHandle.setPickMode(opts)`): 1. **Open** (`opts !== null`): renderer marks `pickModeActive`, sets `alpha = 0.3` on every primitive whose id is neither the source nor in `reachableIds`, mounts an overlay `Graphics` in the origin tile, and subscribes to pointer-move + hover-change + viewport `clicked` + document `keydown`. 2. **Tick** (every pointer-move and hover transition): the renderer asks `computePickOverlay(opts, cursorWorld, hoveredId, points, allIds)` (`src/map/pick-mode.ts`) for a draw spec — anchor ring + cursor line + optional hover outline + dim set — and re-paints the overlay. 3. **Resolve**: a click on a primitive whose id is in `reachableIds` calls `opts.onPick(id)` and tears down. A click on empty space or a non-reachable primitive is a no-op (forgiving for accidental taps mid-pan). Escape (or the imperative `cancel()` on the returned handle) calls `opts.onPick(null)`. 4. **Tear down**: alpha overrides are restored, the overlay `Graphics` is destroyed, every listener is detached, and `pickModeActive` returns to `false`. Existing `onClick` subscriptions are gated on `pickModeActive`, so the standard planet-selection path does not fire on the destination click. The pure overlay-spec helper lives in `src/map/pick-mode.ts` and is covered by `tests/map-pick-mode.test.ts` without booting Pixi. The Pixi side (alpha mutation, `Graphics` overlay, listener hookup) is exercised in the in-browser e2e specs. The Svelte adapter `MapPickService` (`src/lib/map-pick.svelte.ts`) turns the callback contract into `pick(request) → Promise`. The map active view (`lib/active-view/map.svelte`) constructs the service, sets `MAP_PICK_CONTEXT_KEY`, and binds a resolver that translates `sourcePlanetNumber` to the underlying `PickModeOptions` (looking up the source coordinates from the current report). Inspector subsections call `service.pick(...)` and react to the resolved id. ## Hidden primitives `RendererHandle.setHiddenPrimitiveIds(ids)` replaces the current hide-by-id set. Every primitive whose id sits in `ids` has its per-copy `Graphics.visible` flipped to `false` and is skipped by `hitAt`, so a click on its former area falls through to the next visible primitive. An empty set restores everything. Repeated calls are diff-free idempotent — `g.visible` assignments are cheap. The hide set is propagated to `hitTest` through a new optional `hiddenIds` parameter so internal hit-test sites (pointer-move, clicked dispatcher) stay in lock-step with the visible scene. After `setExtraPrimitives` the hide set is re-applied so a freshly-pushed extras layer (cargo-route overlay, pending-Send tracks) does not silently un-hide a primitive whose id is in the current set. The map view (`src/lib/active-view/map.svelte`) computes the set from the per-game `MapToggles` rune + the planet-cascade rule and pushes it on every effect run; toggling a checkbox flips visibility within one frame without a Pixi remount. ## Visible-hyperspace overlay (the "fog") `RendererHandle.setVisibilityFog(circles)` draws (or removes) the fog overlay that highlights the player's visible hyperspace. Each entry describes a circle around a LOCAL planet where the player has scanner / visibility coverage: - An empty list destroys the existing fog rectangles and mask. - A non-empty list rebuilds a single viewport-level `fogLayer` (a sibling below the nine torus copies). `fogPaintOps` returns an ordered op list — one world-sized rectangle filled with `FOG_COLOR` (two shades lighter than the dark theme background) plus one circle per visibility circle. The renderer draws the rectangle ops into `fogLayer` and collects the circle ops into a single `Graphics` set as `fogLayer`'s **inverse stencil mask** (`setMask({ mask, inverse: true })`), so the fog shows everywhere EXCEPT inside the union of the circles. Overlapping circles union for free in the stencil. - Why a mask: earlier iterations subtracted holes with Pixi v8's `Graphics.cut()` (incorrect unions for overlapping holes), then with opaque background-coloured overpaint. The overpaint was a fill-rate cliff — on a large report it painted dozens of near-world-sized opaque circles every frame, which froze panning under Safari's WebGPU backend. An inverse stencil mask rasterises the same circles far cheaper (no blended colour writes, friendly to Apple's tile-based GPU) and stays fully vector, so the fog edge is crisp at any zoom. - The ops carry world-space positions, so wrap mode is baked into the op list rather than into copy visibility: `torus` emits the rectangle and every circle at the nine `{-1,0,1}²` tile offsets; `no-wrap` emits only the central tile. `fogLayer` and the mask are both untransformed children of the viewport, so the coordinates line up. - The fog layer sits below every primitive copy in z-order, so primitives paint on top. - The fog never participates in hit-test. Planet glyphs sit on top of fog, so clicks on visible planets work unchanged. The map view recomputes the fog input only when the report or the `visibleHyperspace` toggle changes, and under render-on-demand a static fog paints no frames at all — the mask-cheap fog cost is only paid on the frames where the camera is actually moving. ## Debug surface The DEV-only `__galaxyDebug` object (defined in `routes/__debug/store/+page.svelte`) exposes `getMapPrimitives()`, `getMapPickState()`, `getMapCamera()`, `getMapFog()`, `getMapMode()`, and `getMapRenderCount()` so e2e specs can assert the renderer's current state without scraping pixels: - `getMapPrimitives()` returns a snapshot of every primitive in the active world: id, kind, priority, current alpha (post-overlay), the explicit fill / stroke colour from its `Style` (no theme fallback), and the `visible` flag mirroring the renderer's hide set. - `getMapPickState()` returns `{ active, sourcePlanetNumber, reachableIds, hoveredId }` — the renderer's view of the current pick session. - `getMapCamera()` returns the current camera + viewport + canvas-origin snapshot, used by e2e specs to assert camera preservation across wrap-mode flips. - `getMapFog()` returns the most recent fog input (the list of circles last passed to `setVisibilityFog`). Empty when the `visibleHyperspace` toggle is off. - `getMapMode()` returns the renderer's current `WrapMode` (`'torus'` or `'no-wrap'`), used to await the remount after a wrap-mode flip. - `getMapRenderCount()` returns the painted-frame count. Under render-on-demand it stays flat while the map is idle and advances only on camera moves or content mutations, so e2e specs can prove the idle map is not repainting. The active map view registers providers on mount via `registerMapPrimitivesProvider` / `registerMapPickStateProvider` / `registerMapCameraProvider` / `registerMapFogProvider` / `registerMapModeProvider` / `registerMapRenderCountProvider` in `src/lib/debug-surface.svelte.ts`, deregisters on dispose, and the surface invokes them lazily on every read. ## Tests - `tests/map-math.test.ts` — `clamp`, `torusShortestDelta`, `distSqPointToSegment`, `screenToWorld`/`worldToScreen`. - `tests/map-no-wrap.test.ts` — `clampCameraNoWrap`, `minScaleNoWrap`, `pivotZoom` (point-under-cursor invariant verified within float64 precision). - `tests/map-hit-test.test.ts` — hand-built cases covering every rule from the algorithm above: hit/miss with default and custom slop (now including `pointRadiusPx`), torus wrap copies, filled vs stroked circles, line endpoint clamping, priority/kind/id ordering, scale effect on slop. - `tests/map-pick-mode.test.ts` — pure-state coverage for `computePickOverlay`: anchor / line / hover-outline / dim-set shape against representative pick configurations. - `tests/e2e/playground-map.spec.ts` — Pixi mount in real browsers, mode toggle, wheel zoom, no-wrap clamp after drag, hit-test plumbing. The unit tests run in jsdom and never touch Pixi or `pixi-viewport`, so a refactor of the renderer cannot silently break them.